KR20170001494A - Current control system for electrode boiler - Google Patents

Abstract

The present invention relates to a current control system for an electrode boiler. The current control system for an electrode boiler comprises: an electrode boiler; a heat storage tank connected to the electrode boiler and storing hot water heated in the electrode boiler; and a supply water temperature descending unit connected to the heat storage tank, receiving a portion of the hot water inside the heat storage tank to be cooled to be supplied to the electrode boiler in order to enable the temperature of supply water supplied to the electrode boiler to be descended at the predetermined temperature or less.

Description

Current control system for electrode boiler

The present invention relates to an electrode boiler current control system, and more particularly, to an electrode boiler current control system capable of stable current control without changing electrolyte concentration.

It is not easy to raise the boiler temperature at low temperatures even in large facilities such as hot springs, buildings, saunas, vinyl houses, greenhouses, and even small houses including general households.

For example, when water is heated by an electrode boiler, the temperature rises at a very low rate at low temperatures, and the water temperature rises at a steep rate above 45 ° C.

Due to these characteristics, as the temperature rises, the current value between the electrodes rapidly increases, and the steam can be filled in the chamber of the electrode boiler.

If the steam is filled in the chamber of the electrode boiler, the electrode rod is in an insulated state, that is, the electrolyte concentration becomes high and the current can not flow any more. Therefore, the function of the electrode boiler for heating the water can be performed It is necessary to develop a technology for a new and advanced type of electrode boiler current control system that can overcome this problem.

Korea Patent Office Application No. 10-1987-0004314 Korea Patent Office Application No. 10-1991-0011250 Korea Patent Office Application No. 10-2005-0095776 Korea Patent Office Application No. 20-1997-0025745

It is an object of the present invention to provide an electrode boiler current control system capable of stable current control without changing the electrolyte concentration.

The object is achieved by an electrode boiler comprising: an electrode boiler; A storage tank connected to the electrode boiler and storing hot water heated by the electrode boiler; And a feed water temperature lowering part connected to the heat storage tank and cooled to receive a part of hot water in the heat storage tank and supply the cooled water to the electrode boiler to lower the temperature of the feed water supplied to the electrode boiler to a predetermined temperature or lower And a control system for controlling the current of the electrode boiler.

The electrode boiler comprises: a chamber; A pair of electrodes disposed in the chamber to heat the water; A water discharge unit provided at a lower end of the chamber and through which water in the chamber is discharged; And a water inflow portion provided at an upper end of the chamber and through which water is introduced into the chamber, and a branch pipe may be connected to the water inflow portion.

Wherein the supply water temperature lowering portion comprises: a cooling tank for cooling water; A fan coil which is disposed apart from the cooling tank and cools water supplied in the cooling tank by evaporation; A first supply water line connecting the heat storage tank and the cooling tank; A second supply water line connecting the cooling tank and the fan coil; And a third supply water line connecting the fan coil and one end of the branch pipe.

A first water circulation pump provided in the third supply water line; A temperature sensor coupled to the chamber of the electrode boiler to sense the temperature in the chamber; A current transformer coupled to the chamber of the electrode boiler; And a control module including a temperature controller connected to the temperature sensor, and a current controller connected to the current transformer and the first water circulation pump, wherein the control module controls the temperature controller and the current controller The operation or operation time of the first water circulation pump can be controlled based on the operation of the first water circulation pump.

A water discharge line connecting the water discharge portion of the electrode boiler and the heat storage tank; A water inflow line connecting the heat storage tank and the other end of the branch pipe; A second water circulation pump provided on the water inflow line; And first and second check valves provided at one end and the other end of the branch pipe to prevent reverse flow of water.

According to the present invention, stable current control can be achieved without changing the electrolyte concentration.

Particularly, according to the present invention, since the time required for heating hot water is reduced, the hot water can be used instantly without having to wait even when hot water is used, so that convenience in use of hot water can be greatly improved and even though a small amount of hot water is used And it is possible to reduce the time or economic loss due to the large amount of water to be heated.

1 is a temperature rise curve of a general water.
2 is a configuration diagram of an electrode boiler current control system according to an embodiment of the present invention.
3 is a control block diagram of the electrode boiler current control system shown in FIG.
4 is a configuration diagram of an electrode boiler current control system according to another embodiment of the present invention.
5 is a control block diagram of the electrode boiler current control system shown in FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent by reference to the embodiments described in detail below with reference to the accompanying drawings.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

In the present specification, the present embodiment is provided to complete the disclosure of the present invention and to fully disclose the scope of the invention to a person having ordinary skill in the art to which the present invention belongs. And the present invention is only defined by the scope of the claims.

Thus, in some embodiments, well known components, well known operations, and well-known techniques are not specifically described to avoid an undesirable interpretation of the present invention.

Like reference numerals refer to like elements throughout the specification. And (used) terms used herein are for the purpose of illustrating embodiments and are not intended to limit the invention.

In the present specification, the singular form includes plural forms unless otherwise specified. Also, components and acts referred to as " comprising (or comprising) " do not exclude the presence or addition of one or more other components and operations.

Unless defined otherwise, all terms (including technical and scientific terms) used herein may be used in a sense commonly understood by one of ordinary skill in the art to which this invention belongs.

Also, commonly used predefined terms are not ideally or excessively interpreted unless they are defined.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a temperature rise curve of a general water.

As shown in this figure, when water is heated by a conventional boiler, for example, the electrode boiler 110 or the second electrode boiler 120 according to the present embodiment, the temperature is raised at a very low rate , And it can be seen that the water temperature rises at a steep speed above 45 ° C.

In other words, it is known that the water is heated at a very high speed when the hot water is heated to the heating turning temperature formed between the temperature of the hot water and the target heating temperature (P1) .

The electrode boiler current control system according to the present embodiment is designed in consideration of the heating characteristics of the water.

Hereinafter, the electrode boiler current control system according to the present embodiment will be described in detail with reference to FIG. 2 and FIG.

FIG. 2 is a configuration diagram of an electrode boiler current control system according to an embodiment of the present invention, and FIG. 3 is a control block diagram of the electrode boiler current control system shown in FIG.

Referring to these drawings, the electrode boiler current control system according to the present embodiment can stably control the current without changing the electrolyte concentration, and includes an electrode boiler 110, a heat storage tank 120, (130).

First, the electrode boiler 110 is a boiler for heating hot water to make hot water. In this embodiment, one electrode boiler 110 is provided. Of course, two or more electrode boilers 110 may be applied. The operation of the electrode boiler 110 can be turned on / off by the control module 190.

Meanwhile, the electrode boiler 110 applied to the present embodiment is a boiler of a totally different concept different from the conventional electric boiler.

A conventional electric boiler is a method in which a heater rod not shown in the drawing is heated and a heated heater rod heats the water.

However, in the case of the electrode boiler 110, there is no heater rod, and the electrode rod 112 is applied.

No heat is generated in the electrode rod 112 even if electricity is supplied. Instead, when electricity is applied to the electrode rod 112, water between them is ionized, and water molecules act as flow resistors to generate Joule heat of 860 Kcal / Kw. As the temperature of the water rises, the resistance value of the water rises more rapidly, so that the desired high temperature water can be obtained in a shorter time.

The generated heat is vaporized at a low temperature due to the heating medium flow path in the electrode rod 112, thereby further improving the thermal conductivity and amplifying the heat to water by rapid thermal diffusion, thereby heating the water faster, .

The electrode boiler 110 is known to have an energy saving efficiency of 20% or more as compared with the conventional electric boiler. In this embodiment, the electrode boiler 110 having such advantages is applied.

The electrode boiler 110 includes a chamber 111 for forming a space into which water is introduced and an electrode rod 112 disposed in the chamber 111 so as to be spaced apart from each other and to heat the water.

At the lower end of the chamber 111, a water discharging portion 113 through which the water in the chamber 111 is discharged is provided. A water discharge line (L1) is connected to the water discharge portion (113). Water of the electrode boiler 110 can be supplied to the heat storage tank 120 through the water discharge unit 113 and the water discharge line L1.

At the upper end of the chamber 111, a water inflow part 114 through which water flows into the chamber 111 is provided.

A branch pipe 160 having one end and the other end is connected to the water inlet 114. At this time, the water inflow line (L2) is connected to the other end of the branch pipe (160) and the heat storage tank (120). Water in the storage tank 120, that is, hot water as heating water can be supplied to the chamber 111 of the electrode boiler 110 through the water inflow line L2 and the other end of the branch pipe 160.

The second water circulation pump 152 is provided in the water inflow line L2. The operation of the second water circulation pump 152 can also be controlled by the control module 190.

First and second check valves 171 and 172 are provided at one end and the other end of the branch pipe 160 to prevent reverse flow of water. The backflow of the water inflow part 114 does not occur due to the first and second check valves 171 and 172. [

Next, the heat storage tank 120 is connected to the electrode boiler 110, and the hot water heated by the electrode boiler 110 is stored. The capacity of the tank can be changed at any time.

The heat storage tank 120 and the electrode boiler 110 can be connected by the water discharge line L1 and the water inflow line L2 as described above.

The supply water temperature lowering part 130 is connected to the heat storage tank 120 and receives part of the hot water in the heat storage tank 120 to cool the same and supply the cooled water to the electrode boiler 110, And serves to lower the temperature below a predetermined temperature.

That is, as described later, in the present embodiment, the current controller 196 of the control module 190 controls the first water circulation pump 151 so that the supply water temperature drop including the cooling tank 134 and the fan coil 135 The water from the heat storage tank 120 is cooled and supplied to the chamber 111 through the cooling unit 130.

In other words, in the present embodiment, the cooled water is supplied at one end of the branch pipe 160 and the hot water in the storage tank 120 is directly supplied to the other end of the branch pipe 160, It is possible to supply the feed water by lowering the temperature of the feed water to an appropriate temperature. Therefore, stable current control can be performed without changing the concentration of the electrolyte in the chamber 111. [

The supply water temperature lowering part 130 includes a cooling tank 134 for cooling water and a fan coil for cooling the water supplied in the cooling tank 134 by the evaporation action, A first supply water line 131 connecting the storage tank 120 and the cooling tank 134 and a second supply water line 132 connecting the cooling tank 134 and the fan coil 135, And a third supply water line 133 connecting the fan coil 135 and one end of the branch pipe 160. The hot water in the thermal storage tank 120 can be cooled by the supply water temperature lowering part 130 through the supply water temperature lowering part 130.

The first water circulation pump 151, the temperature sensor 181, the current transformer 182, and the control module 190 are further provided in the electrode boiler current control system according to the present embodiment.

The first water circulation pump 151 is provided in the third supply water line 133 constituting the supply water temperature lowering part 130 and pumps the water flowing along the third supply water line 133.

The temperature sensor 181 is coupled to the chamber 111 of the electrode boiler 110 to sense the temperature in the chamber 111. The sensed information is transmitted to the temperature controller 191 of the control module 190.

The current transformer 182 is coupled to the chamber 111 of the electrode boiler 110. The current transformer 182 is a device for reducing the large current to a small current or lowering the high voltage to a low voltage so that the current is easily measured. Lt; / RTI >

Finally, the control module 190 includes a temperature controller 191 connected to the temperature sensor 181 and a current controller 192 connected to the current transformer 182 and the first water circulation pump 151. The control module 190 controls the operation or operation time of the first water circulation pump 151 based on the control signals of the temperature controller 191 and the current controller 192.

The control module 190 may further include a central processing unit 191 (CPU), a memory 192 (MEMORY), and a support circuit 193 (SUPPORT CIRCUIT).

The central processing unit 191 can be industrially applicable to control the operation or operation time of the first water circulation pump 151 based on the control signals of the temperature controller 191 and the current controller 192 in this embodiment May be one of a variety of computer processors.

The memory 192 (MEMORY) is connected to the central processing unit 191. The memory 192 is a computer-readable recording medium that may be installed locally or remotely and may be any of various types of storage devices such as, for example, random access memory (RAM), ROM, floppy disk, hard disk, At least one or more memories.

A support circuit 193 (SUPPORT CIRCUIT) is coupled with the central processing unit 191 to support the typical operation of the processor. Such a support circuit 193 may include a cache, a power supply, a clock circuit, an input / output circuit, a subsystem, and the like.

In this embodiment, the control module 190 controls the operation or operation time of the first water circulation pump 151 based on the control signals of the temperature controller 191 and the current controller 192.

At this time, a series of processes or the like for controlling the operation or operation time of the first water circulation pump 151 based on the control signals of the temperature controller 191 and the current controller 192 may be stored in the memory 192. Typically, software routines may be stored in memory 192. The software routines may also be stored or executed by other central processing units (not shown).

Although processes according to the present invention are described as being performed by software routines, it is also possible that at least some of the processes of the present invention may be performed by hardware. As such, the processes of the present invention may be implemented in software executed on a computer system, or in hardware such as an integrated circuit, or in combination of software and hardware.

The cold water cooled at one end of the branch pipe 160 is supplied to the chamber 111 through the control of the control module 190 and the hot water in the storage tank 120 is supplied to the other end of the branch pipe 160. [ The temperature of the supply water can be lowered to an appropriate temperature without supplying only hot water as in the past. Therefore, stable current control can be performed without changing the concentration of the electrolyte in the chamber 111. [

According to this embodiment having such a structure and action, stable current control can be performed without changing the electrolyte concentration unlike the past.

Particularly, according to the present embodiment, since the time required for heating the hot water is reduced, the hot water can be used instantly without having to wait even when using the hot water in the cold winter, It is possible to reduce the temporal or economic loss due to the need to heat a large amount of water.

FIG. 4 is a configuration diagram of an electrode boiler current control system according to another embodiment of the present invention, and FIG. 5 is a control block diagram of the electrode boiler current control system shown in FIG.

Referring to these drawings, the electrode boiler current control system according to the present embodiment may also include an electrode boiler 110, a thermal storage tank 120, and a feed water temperature lowering part 230.

The supply water temperature lowering part 230 includes a cooling tank 134 for cooling the water and a fan coil for cooling the water supplied from the cooling tank 134 by the evaporation action, A first supply water line 131 connecting the storage tank 120 and the cooling tank 134 and a second supply water line 132 connecting the cooling tank 134 and the fan coil 135, And a third supply water line 133 connecting the fan coil 135 and one end of the branch pipe 160.

In this structure, the first supply water line 131 of the supply water temperature lowering part 230 is further provided with a solenoid valve 285 for interrupting the flow of the first supply water line 131.

The sol valve 285 can be controlled by the control module 290 as a solenoid valve. That is, the control module 290 may control the water to flow toward the supply water temperature lowering part 230 by closing the solenoid valve 285 when the water heating temperature is a certain temperature, for example, 45 ° C or lower.

Even if the present embodiment is applied, stable current control can be performed without changing the electrolyte concentration unlike the past.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It is therefore intended that such modifications or alterations be within the scope of the claims appended hereto.

110: electrode boiler 111: chamber
112: Electrode 113: Water discharging portion
114: water inlet 120: storage tank
130: feed water temperature lowering part 131: first feed water line
132: second supply water line 133: third supply water line
134: cooling tank 135: fan coil
151: first water circulation pump 152: second water circulation pump
160: branch pipes 171, 172: first and second check valves
181: Temperature sensor 182: Current transformer
190: Control module 195: Temperature controller
196: Current controller

Claims (5)

Electrode boiler;
A storage tank connected to the electrode boiler and storing hot water heated by the electrode boiler; And
And a supply water temperature lowering part connected to the thermal storage tank and cooled to receive a part of hot water in the thermal storage tank and supply the cooled water to the electrode boiler to lower the supply water temperature supplied to the electrode boiler to a predetermined temperature or lower. An electrode boiler current control system.
The method according to claim 1,
Wherein the electrode boiler comprises:
chamber;
A pair of electrodes disposed in the chamber to heat the water;
A water discharge unit provided at a lower end of the chamber and through which water in the chamber is discharged; And
And a water inflow portion provided at an upper end of the chamber and through which water is introduced into the chamber,
And a branch pipe is connected to the water inflow portion.
3. The method of claim 2,
Wherein the supply water temperature lowering portion comprises:
A cooling tank for cooling the water;
A fan coil which is disposed apart from the cooling tank and cools water supplied in the cooling tank by evaporation;
A first supply water line connecting the heat storage tank and the cooling tank;
A second supply water line connecting the cooling tank and the fan coil; And
And a third supply water line connecting the fan coil and one end of the branch pipe.
The method of claim 3,
A first water circulation pump provided in the third supply water line;
A temperature sensor coupled to the chamber of the electrode boiler to sense the temperature in the chamber;
A current transformer coupled to the chamber of the electrode boiler; And
Further comprising a control module having a temperature controller coupled to the temperature sensor and a current controller coupled to the current transformer and the first water circulation pump,
Wherein the control module controls the operation or operation time of the first water circulation pump based on a control signal of the temperature controller and the current controller.
3. The method of claim 2,
A water discharge line connecting the water discharge portion of the electrode boiler and the heat storage tank;
A water inflow line connecting the heat storage tank and the other end of the branch pipe;
A second water circulation pump provided on the water inflow line; And
Further comprising first and second check valves provided at one end and the other end of the branch pipe to prevent reverse flow of water.

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